Standard Operating Procedure for Zooplankton Analysis LG403 Revision 07, July 2016


Standard Operating Procedure for

Zooplankton Analysis

LG403

Revision 07, July 2016

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TABLE OF CONTENTS

Section

Number	Subject	Page

I.0	SCOPE AND APPLICATION	1

2.0	SUMMARY OF METHOD	1

3.0	SAMPLE COLLECTION AM) PRESERVATION	 1

4.0	APPARATUS	1

5.0	REAGENTS	2

6.0	ANALYTICAL PROCEDURE ^ MICROCRUSTACEAN SAMPLE ANALYSIS	2

7.0	ANALYTICAL PROCEDURE ^ ROTIFER SAMPLE ANALYSIS	5

8.0	CALCULATION OF MICROCRUSTACEAN AND ROTIFER BIOMASS	6

9.0	CALCULATIONS AM) REPORTING	8

10.0 QUALITY CONTROL AUDITS AND METHODS PRECISION	10

II.0	SAFETY AND WASTE DISPOSAL	10

12.0 REFERENCES	10

FIGURE 1: ZOOPLANKTON SAMPLE SPLITTING DIAGRAM	12

APPENDIX 1: CRUSTACEAN FORMULA FACTORS	13

APPENDIX 2: ROTIFER BIOMASS FORMULA FACTORS	17

Disclaimer: Mention of trade names or commercial products does not constitute endorsement or recommendation for use.

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Standard Operating Procedure for Zooplankton Analysis

Standard Operating Procedure for Zooplankton Analysis

1.0	SCOPE AND APPLICATION

1.1	This method, as developed from Gannon (1971), Stemberger (1979) and Evans etal. (1982), is used to identify
and enumerate the zooplankton populations from the Great Lakes.

2.0	SUMMARY OF METHOD

2.1	The method involves microscopic examination of preserved zooplankton samples collected with a conical net
towed vertically through a water column. Microcrustacea are examined in four stratified aliquots under a
stereoscopic microscope. Rotifera are examined in two equal volume sub-samples under a compound
microscope.

3.0	SAMPLE COLLECTION AND PRESERVATION

3.1	See U.S. EPA GLNPO Standard Operation Procedure (SOP) for Zooplankton Sample Collection and Preservation
(LG 402).

4.0	APPARATUS

4.1	Most supplies can be acquired from biological supply companies (such as Wildlife Supply Company). The
supplies needed are as follows:

Dissecting microscope with lOxto 5Ox magnification
Compound microscope with lOOxto lOOOx magnification
1-mL Calibrated Hensen-Stempel pipette
100-, 250- and 500-mL graduated cylinders
Folsom plankton splitter

Ward counting wheel or other suitable counting chamber

Sedgwick-Rafter counting cell

Cover glass for Sedgwick-Rafter counting cell

Microscope slides, 1x3 inch

Cover slips

Tubes for concentrating plankton samples (see below)

Small sieves with 63- and 500-(.un mesh

63-|im Nitex mesh

Heavy duty rubber bulb

Microprobe

Micro-forceps

100- to 500-mL glass jars with split fractions written on labels (2-2048)

4.2	The plankton concentrating tube is constructed by covering one end of a wide glass tube (such as a
chromatography tube) with 64-|im mesh. The mesh is secured with O-rings and a heavy-duty bulb is attached to
the other end to provide suction.

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5.0 REAGENTS

5.1 Reagents can be ordered through chemical supply companies. CMC has been acquired through Master's
Company, Inc.

5.2 The reagents needed are as follows:

Formalin (37% formaldehyde solution)

Ethanol

5% Sodium hypochlorite solution (Clorox bleach)

CMC-9, CMC-10, Hoyer's or other suitable mounting medium for mounting and clearing slide-archived
specimens

Rose Bengal stain dissolved in ethanol
Dilute solution of laboratory detergent

6.0 ANALYTICAL PROCEDURE: MICROCRUSTACEAN SAMPLE ANALYSIS

6.1 Microcrustacean Stratified Splitting

6.1.1 When zooplankton samples are returned to the lab, approximately 1 to 3 mL of Rose Bengal stain solution
may be added to each sample to aid in finding the smaller organisms. Samples should be processed one at
a time. Under the hood, rinse the sample from the sample bottle through a 63-|im (or smaller) mesh sieve
with DI water to remove the formalin. Set the formalin aside under the hood in a sealed labeled bottle to
use at the completion of analysis (see 7.4)

6.1.2 Be sure to rinse the sample bottle thoroughly with DI water into the 63-|im (or smaller) mesh sieve to
remove any residual organisms adhering to walls of the bottle. All containers from which zooplankton
are transferred are to be rinsed thoroughly, including the Folsom splitter, glass jars, and counting
chambers. Wash the sample into a glass jar. Adding a small amount of dilute laboratory soap to each
sample at this time aids in preventing organisms from sticking to the sides of the containers and from
floating at the surface of the sample.

6.1.3 If the sample contains large clumps of Cercopagis, then:

6.1.3.1 Carefully remove the clumps with forceps and place them in a glass tray.

6.1.3.2 Gently rinse the clumps with a stream of DI water in the tray, while pulling at the clumps with
forceps to free trapped organisms.

6.1.3.3 Return "freed" organisms other than Cercopagis and Bythotrephes and rinse water to the sample
and split as usual.

6.1.3.4 Reserve the clumps of Cercopagis in a separate jar and subsample if abundant (> 250 individuals,
see 6.2.1.5). Also note all Bythotrephes identified during this counting process.

6.1.4 Stir the sample gently to break up algal clumps and then pour the entire sample into the Folsom plankton
splitter. Stir the sample again in a figure-8 pattern to distribute animals uniformly and split the sample by
immediately rotating the splitter before the organisms can settle. Rinse the inside of the splitter well to
remove organisms that may stick to the sides. Rinse one sub-sample from the splitter receiving trays and
save it in a labeled jar indicating the fraction of total original volume it contains.

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6.1.5 The second sub-sample from the split is placed in the Folsom plankton splitter and divided again. One
sub-sample is saved in a labeled jar indicating the fraction of the total original volume it contains.

6.1.6 Repeat Steps 6.1.4 and 6.1.5 as many times as necessary until the last 2 sub-samples contain at least 200
and no more than 400 microcrustaceans each (not including nauplii). These 2 sub-samples represent
equal fractions of the original sample. One sub-sample is saved in a jar with the appropriately labeled
split, and the other sub-sample is saved in ajar labeled "B".

6.2 Microcrustacean Enumeration

6.2.1 Four sub-samples are to be examined and enumerated. The sub-sample is concentrated by using the small
sieve or the condensing tube and placed in a circular (or other suitable) counting chamber. All
microcrustaceans are identified and enumerated under a dissecting microscope. The four sub-samples are
counted using the criteria listed below in 6.2.1.1, 6.2.1.2, and 6.2.1.3. Refer to Figure 1 for a diagram of
the splitting process.

6.2.1.1 The final two sub-samples which contain 200 - 400 organisms (see 6.1.6) are to be counted first.
These are referred to as the A and B Counts. All microcrustaceans (except nauplii) are examined
and enumerated. The first twenty intact individuals for each SPECCODE are measured for length
(Section 8.1). If the sub-samples contain a large amount of algae, it may be necessary to pick out
the organisms and transfer them to a clean counting chamber prior to identification.

6.2.1.2 A third sample equal in fraction to the sum of the first two (A + B) samples is examined for
subdominant taxa (taxa encountered less than 40 times in A and B counts combined). This is the
C Count.

6.2.1.3 A fourth sub-sample equal in fraction to the sum of the first three (A, B, and C) counts is
examined for large taxa. This is the D count. Large taxa include Limnocalanus macrurus,
Senecella calanoides, Epischura lacustris, Holopedium gibberum, Diaphanosoma birgei,
Leptodora kindti and Polyphemus pediculus. If a taxon defined as "large" has a sum of more than
40 individuals in counts A, B, and C, it is not necessary to enumerate them in D count.

6.2.1.4 When a taxa is detected during this sequence of subsampling, all subsamples that this taxa was
searched for but not found are referred to as true zero counts. Subsamples for which these taxa
were not searched for should be identified with a "-1" in the submission file. In the data
submission, number of a taxa for the entire sample (NUMJAR) is calculated by dividing the sum
of all subsample counts for a taxa by the proportion of the sample searched.

6.2.1.5 The entire sample must be examined for Mysis, Bythotrephes and Cercopagis. All individuals are
counted, but only the first twenty individuals encountered for these three taxa are measured. As
previously described, they can be removed from the sample prior to splitting if they are
numerous. Otherwise they should be enumerated from A, B, C and D splits as they are examined.
After these splits have been counted, pour the uncounted portion through a 500-(.un mesh sieve.
Examine the organisms trapped in the sieve for the three taxa. All counts for these three taxa refer
to the entire sample (WHOLE, split factor 1). If Cercopagis is numerous (> 250), subsampling of
the clump is appropriate. Weighing the clump and the subsample removed provide an estimate of
proportion counted, enabling the expansion to an estimate of the whole sample count. The
balance used should have precision of at least O.OOlg. Remove as much water as possible from
the wet clump before weighing and subsampling. The number reported in the data submission is
the estimate for the whole sample, but sample notes should report that this subsampling occurred
and include the weights of the clump and subsample and the count of the subsample.

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6.2.1.6 If a backlog in sample analysis occurs, the GLNPO project officer can give permission for a

deviation in the protocol for the analysis of D20 counts that omits the "B" subsample. NUMJAR
is calculated from only the subsamples searched as described in 6.2.1.4. In this case, if 20 or
more individuals of a taxa are counted in the "A" subsample, the analyst does not need to search
for the taxa in the "C" subsample. This deviation in sample analysis was granted for: Lake
Michigan 2012 Summer, Lake Erie 2012 Spring and Summer, all lakes excepting Lake Ontario
2013 Spring and Summer, Lake Superior 2014 Spring.

6.2.2 General Analysis Guidelines

6.2.2.1 Those organisms requiring higher magnification for identification are examined at 100 - lOOOx
magnification under a compound microscope.

6.2.2.2 While counting Microcrustacea, make sure that all organisms are settled to the bottom. It is
possible to sink floating Microcrustacea by gently pressing them down using the microprobe or
by adding a drop of dilute laboratory detergent.

6.2.2.3 It is necessary to identify and record the sex of all mature Copepods encountered.

6.2.2.4 If replicate samples are collected in the field, all samples from that station should be analyzed by
the same analyst. Shallow and deep tows from each station should also be analyzed by the same
analyst.

6.2.2.5 If a sample cannot be completely counted and archived within 2 days, the sample should be kept
in the refrigerator and a few drops of formalin can be added to the jars to prevent organisms from
clumping. Sample analysis should not extend beyond four days.

6.2.2.6 In order to check for consistency of identification and enumeration, analysts can compare their
microcrustacean and rotifer results with historical data. On some occasions, analysts may choose
to re-examine archived samples in order to confirm identifications or to clarify taxonomic
problems.

6.2.2.7 Occasionally, organisms are encountered which do not already appear on the species list. After
the taxonomic status of such an organism is determined, the organism should be placed in a
labeled vial and preserved with ethanol. The label in the vial should include genus/species name,
date preserved, analyst initials, station number, and sample number. This will serve as a voucher
specimen. The voucher specimen should be sent out for external confirmation, then a report
made to the Work Assignment Manager (WAM) including the distinguishing characteristics used
to identify the new organism, and suggestions as to why it has not been encountered in the past
(e.g., it is primarily benthic or littoral). Only AFTER written notification of acceptance of the
new organism by the WAM should that species be added to the species list.

6.2.2.8 In order to help assure consistency of identification, a voucher specimen collection, based on the
species list, should be maintained. Voucher specimens are preserved and stored as stated in
6.2.2.7.

6.2.2.9 It is important that the voucher specimens are checked periodically so lost or damaged animals
can be replaced. At least one male and one female (preferably 3-5) representative specimen
should be available at all times for examination.

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Standard Operating Procedure for Zooplankton Analysis

6.3 Taxonomic References

6.3.1 Adult calanoids are identified according to Balcer el al. (1984). Adult cyclopoids and Harpacticoids are
identified according to Hudson el al. (1998). Immature calanoids and cyclopoids are identified to the
lowest taxonomic level possible, usually suborder or genus (Czaika 1982). Nauplii are counted with
rotifers. Hudson and Lesko (2003) provides supplementary information on Great Lake copepod
identification. Malacostracans (i,e.,Mysis relicta) are identified according to Mauchline (1980).
Malacostracans are not collected efficiently with our zooplankton tows but they are enumerated and
measured for historical purposes. The following cladocerans are identified according to Balcer el al.
(1984): Leptodora kindtii, Polyphemuspediculus, Holopedium gibberum, and Diaphanosoma birgei.
Brooks (1959) and Evans (1985) are used for all Daphnidae. The remaining cladocerans (Chydoridae,
Bosminidae, and Macrothricidae) are classified according to Brooks (1959). Members of Cercopagidae
(i.e., Bythotrephes longimanus, and Cercopagis pengoi) are identified according to Rivier (1998).

7.0 ANALYTICAL PROCEDURE: ROTIFER SAMPLE ANALYSIS

7.1 Rotifer, Nauplii and Veliger Sub-sampling

7.1.1 Rotifers, nauplii, and veligers are only counted from the tow taken with the 63-fxm mesh net. Tows taken
with the larger mesh (153-|im) will not capture sufficient numbers of these small taxa.

7.1.2 Selection of the split level from which aliquots for rotifer enumeration are taken is based on estimates
from previous samples within the data set, or from estimates made during microcrustacean enumeration
(rotifers are visible in the dissecting microscope).

7.1.3 Separate 1-mL aliquots are taken from the appropriate split, and rotifers, nauplii and veligers are counted
from these aliquots. The goal is to count 200 to 400 animals (rotifers and nauplii, not including veligers).
The sample should be mixed thoroughly, and the 1-mL aliquot withdrawn with a Hensen-Stempel pipette
(or other precalibrated large-bore pipette). In cases when less than 200 animals are encountered in the 1-
mL aliquot, additional 1-mL aliquots can be used for each count (see 7.1.5).

7.1.4 Repeat this process for a duplicate count. These are referred to as A and B counts.

7.1.5 In cases of extremely low rotifer densities, the sample may be concentrated prior to taking aliquots with
the pipette. The maximum number of 1-mL aliquots counted from an unsplit sample is 3 per count (i.e., a
total of 6 mL), even if the sum does not reach 200 organisms.

7.2 Sedgwick-Rafter Cell Preparation and Rotifer Enumeration

7.2.1 The 1-mL aliquot is placed in a Sedgwick-Rafter cell and covered with a glass cover slip.

7.2.2 All rotifers, microcrustacean nauplii, and Dreissena veligers are identified and enumerated under a
compound microscope at lOOx magnification. Length measurements are done on the first 20 intact
individuals encountered. Some rotifer species require width measurements (Section 8.2).

7.2.3 Veligers are enumerated for historical record with recognition of the variability in the reproductive cycle
of Dreissena. If veligers are extremely abundant (> 100) in the A count, they do not need to be counted
in the B count but that deviation must be noted. In those cases, a "-1" should be entered in the ROTB
field and ROTAB=ROTA.

7.2.4 After the counts are completed, volume of the split used, including the volume of the aliquots, is
measured, and this information and the split factor is recorded in the count spreadsheet.

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7.3 Taxonomic References

7.3.1 Rotifers are identified to genus and to species where possible according to Edmondson (1959) and

Stemberger (1976). Some rotifers may be indistinguishable by their gross morphology because of their
contracted state; therefore, identification of these organisms is determined by examination of their
chitinous mouthparts after using sodium hypochlorite bleach as a clearing agent (Stemberger 1979). This
is a time-consuming process that destroys the rotifer and does not often produce clear results. Therefore,
in an effort to use lab time efficiently, the bleaching process is most commonly used only as a training
technique or in the instance of fairly common organisms with questionable identification.

7.4 Archiving Microcrustacean and Rotifer Samples

7.4.1 After analysis all subsamples are concentrated and returned to the original labeled sample bottle with the
original formalin solution from that sample (see 6.1.1).

7.4.2 Sample archiving for a sample set is done after the data submission has been reviewed and accepted.
When time to archive, the surface water is siphoned off using a condenser tube or the sample is
concentrated using the 63-|im mesh (or smaller) sieve. The concentrated sample is transferred to a 125-
mL glass Qorpak bottle.

7.4.3 Fill the sample bottle close to the top with DI and add approximately 5 mL of 37% formalin solution to
the sample.

7.4.4 Label the bottle and the storage box with lake, station, lab number, and sample number. All archiving
information should be computerized using a word processing program.

8.0 CALCULATION OF MICROCRUSTACEAN AND ROTIFER BIOMASS

8.1 Microcrustacean Biomass

8.1.1 Biomass (dry weight in |ig) of microcrustaceans is calculated from formulas relating some linear

measurement (usually body length in mm) to body weight. A compilation of the formula references and
constants can be found in Appendix 1. Formulas are derived from a number of sources, but are of the
general form:

Overall biomass for a taxa is calculated by averaging the dry mass of up to the first 20 measured individuals and
multiplying by the density.

8.1.2 Zooplankton may be measured by use of a calibrated eyepiece micrometer or camera lucida/tablet system
during the identification and enumeration process, or they may be removed from the sample,
photographed with a digital camera, and measurements calculated from the images. The first twenty
intact individuals are measured for each taxa.

In W = In a + b \nL

where:

In w

In a and b
In L

natural logarithm of the dry weight estimate (fig)
species specific constants (listed in appendix)
the length of a measured individual (mm).

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Cladocera: Length from the top of the head to the base of the caudal spine or to the end of the carapace.
Copepoda: Length from tip of the head to the insertion of spines into the caudal ramus.

Mysis: Carapace length, or the length from the tip of the head to the cleft in the telson.

Bythotrephes: Body length, excluding the caudal process.

Cercopagis: Body length, from the top of the eye to the end of the caudal claws.

NOTE: If the organisms are curved or bent, several straight line measurements should be made and
summed to obtain total length.

8.1.3	Since the length/weight relationship for Holopedium gibberum was developed based on the length of the
foot, the equation from the original reference (Persson and Ekbohm 1980) has been modified for input of
the total length, that is assumed to be 4 times the foot length.

8.1.4	Copepoda nauplii follow a length-weight equation appropriate for all life stages of copepods developed
by Bottrell et al. 1976. The equation coefficients are in the crustacean factor list (Appendix 1).

8.1.5	Dreissenid veligers follow a length-weight equation developed by Kelly Bowen DFO Canada (personal
communication).

weight (|ig) = 0.025eA17.5(L in mm)

This equation is appropriate for individuals smaller than 300 (.un.

8.2 Rotifer Biomass

8.2.1 Rotifer biomass (|_ig) is calculated according to A. Ruttner-Kolisko (appendix in Bottrell et al. 1976). For
most rotifers, calculations use a formula (EQ #1 in Appendix 2) with the general form:

Rotifer biomass (|ig) = [(length3 x FF) + (%BV x length3 x FF)] x 10"6 x WW : DW

where:

jug	=	biomass of individual

Length	=	total length in |a,m

FF	=	species specific formula factor (see Appendix 2)

% BV	=	volume of appendages as a percent of body biovolume (see Appendix 2)

10"6	=	conversion to wet weight; assuming a density of 1

WW:DW	=	wet weight to dry weight conversion (see 8.2.2)

Note that the units of length and width measurements are in |_im in the rotifer formulas and in mm in the
crustacean formulas.

8.2.2 A wet weight/dry weight conversion factor of 0.1 (Doohan, 1973) is used for all genera except
Asplanchna, for which a factor of 0.039 (Dumont et al., 1975) is used.

8.2.2 For the genus Collotheca, width is measured, and the following formula (EQ #2 in Appendix 2) used:

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Collotheca biomass (|ig) = (width3 x FF) x 10"6 x WW : DW

8.2.4 For the genera Conochiloides, Conochilus, Filinia, and Trichocerca, both length and width are measured,
and the following formula (EQ #3 in Appendix 2) used:

Biomass (|ig) = [(length x width2 x FF) + (%BV x length x width2 x FF)] x 10"6 x WW : DW

8.2.5 The genera Conochiloides and Conochilus, have no appendages (%BV=0) that removes one term from
the equation above:

8.2.6 Measurements are made for all intact individuals as follows:

8.2.6.1	Loricate forms: body length from corona to the opposite end at the base of spine (if present).

8.2.6.2	Non-loricate forms: body length from corona to the opposite end, excluding spines, paddles,
"toes" or other extensions.

9.0	CALCULATIONS AND REPORTING

9.1	Zooplankton data are reported as number of organisms per cubic meter, which are calculated as follows:
9.1.1 Volume of water filtered:

V = a NR A

where:

V	=	Volume of water filtered (m3)

a	=	Flow meter calibration factor (see 9.2)

Nr	=	Number of revolutions (read from the flow meter dial)

A	=	Area of the mouth of the net (m2) = 0.19634954 m2 for 0.5-m diameter net

9.1.2 Microcrustacean Densities

D = N/(Pt*V)

where:

D = Density of organisms in numbers per cubic meter
N = Number of organisms counted in all splits searched

Pt = The proportion of the total sample used to enumerate the taxon (sum of all inverse split factors).

V	= Volume of water filtered (from 9.1.1)

The overall count for a specific taxa in an entire sample is calculated by dividing the total number of
organisms counted in all searched splits by the proportion of the sample in which each taxa was enumerated.

9.2 Flowmeters are calibrated during each cruise (see Zooplankton Sample Collection SOP, LG402). The calibration
factor is calculated by dividing tow depth in meters by the average number of flowmeter counts recorded during
the tows. This information should be recorded in the field notebook for each cruise, and also entered into the field
sampling spreadsheet and database.

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9.2.1 The formula for flowmeter calibration is as follows:

d

a = 	

N

R (ave)

where:

a = Flowmeter calibration
d = Sample depth in meters

NR(ave) = Number of flowmeter counts, averaged for 20 calibration tows
9.3 Rotifer (and Nauplii) Densities

9.3.1 Calculate the densities of rotifers and nauplii using the following formula:

D = (N*Vs)/(Na*V*Ps)

where:

D	= Density of organisms in number per cubic meter

N	= Number of organisms

Na	= Number of 1-mL aliquots examined

Vs	= Volume of split from which aliquots were removed in ml (including aliquots)

Ps	= The proportion of the total sample represented by the volume from which aliquots were removed

(inverse of split factor).

V	= Volume of water filtered in m3 (from 9.1.1)

Density is calculated from the sum of individual counts (ROTAB) taking in consideration the total subsample

volume searched (sum of SUBMLA and SUB MLB). For veligers where no B count is done, ROTA
is multiplied by 2.

9.4	Data Entry

9.4.1 All microcrustacean and rotifer calculations are made using a spreadsheet program such as Excel or a
database program such as Microsoft Access.

9.5	Data Submission to GLNPO

9.5.1	A multi-worksheet Excel data file can be initially submitted electronically for initial review. After final
approval the following items are to be submitted on a CD including a cover letter. The date written on the CD
should be the date of last changes to the approved data file on the disc.

9.5.2	The data as an Excel file in the GLNPO zooplankton template format.

9.5.3	Electronic copies of all field sheets (pdf format), laboratory count sheets (Excel) and Access database.

9.5.4	Backup/duplicate CD's or DVD's must be made of all data disks submitted to EPA.

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10.0 QUALITY CONTROL AUDITS AND METHODS PRECISION

10.1 In general, ten percent of all samples analyzed are analyzed in duplicate by a second analyst. If a data set has less
than 10 samples, at least one sample from that data set should also be analyzed in duplicate.

10.2 For QA counts, the second analyst counts the same split for crustaceans and the same Sedgewick Rafter cell
aliquots for rotifers, so that only interanalyst variation is quantified, and not variation associated with sub-

10.3 Results from the second analyst are reported under the same sample number as the original sample, with the
exception that the seventh character is replaced by a "Q."

10.4 Percent similarity will be calculated for the samples analyzed in duplicate by two analysts, according to the
following formula:

a and b are, for a given species, the relative proportions of the total samples A and B, respectively, which that
species represents.

10.5 It is expected that the two counts should have a similarity of 90%. If not, the reasons for the discrepancies
between analysts should be discussed. If a major difference is found in how the two analysts have been
identifying organisms, the last batch of samples that have been counted by the analyst under review may have to
be recounted.

11.0 SAFETY AND WASTE DISPOSAL

11.1 Proper PPE should be worn in the laboratory while handling and preparing samples for analyses. Follow all
laboratory waste disposal guidelines regarding the disposal of formalin (37% formaldehyde) solutions. Do not
discard formalin solutions into the sink unless previously diluted as directed by your laboratory health and
safety officer.

12.0 REFERENCES

12.1 Balcer, M.D., N.L. Korda and S.I. Dodson. 1984. Zooplankton of the Great Lakes. A guide to the identification
and ecology of the common crustacean species, 174p. Univ. Wise. Press. Madison.

12.2 Bottrell, H.H., A. Duncan, Z.M. Gliwicz, E. Grygierek, A. Herzig, A. Hillbricht-Ilkowska, H. Kurasawa, P.
Larsson and T. Weglenska. 1976. A review of some problems in zooplankton production studies. Norw. J. Zool.

12.3 Brooks, J.L. 1959. Cladocera, p. 587-656. In: W.T. Edmondson (ed.) Freshwater Biology, 2nd Ed., Wiley, New
York, pp. 1248.

12.4 Czaika, S.C. 1982. Identification of nauplii N1-N6 and copepodids CI-CVI of the Great Lakes calanoid and

sampling.

where:

24: 419-456.

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cyclopoid copepods (Calanoida, Cyclopoida, Copepoda). J. Great Lakes Res. 8:439-469.

12.5	Doohan, M. 1973. An energy budget for adult Brachionusplicatilis Muller (Rotatoria). Oecologia. 13: 35 1-362.

12.6	Dumont, H.T, van de Velde, I. and Dumont, S. (1975) The dry weight estimate of biomass in a selection of
Cladocera, Copepoda and Rotifera from the plankton, periphyton, and benthos of continental waters. Oecologia
19: 225-246.

12.7	Edmondson, W.T. 1959. Rotifers, p. 420-494. In: W.T. Edmondson (ed.) Fresh-water Biology, 2nd Ed., Wiley,
New York, pp. 1248.

12.8	Evans, M. 1985. The morphology of Daphniapulicaria, a species newly dominating the offshore southeastern
Lake Michigan summer Daphnia community. Trans Amer. Micro. Soc. 104: 223-231.

12.9	Evans, M.S., D.W. Sell and D.I. Page. 1982. Zooplankton studies in 1977 and 1978 at the Donald C. Cook
Nuclear Power Plant: Comparisons of preoperational (1971-1974) and operational (1975-1970) population
characteristics. Univ. Michigan. Great Lakes Res. Div. Spec. Rep. 89.

12.10	Gannon, J.E. 1971. Two counting cells for the enumeration of Zooplankton micro-Crustacea. Trans Amer.
Micros. Soc. 90: 486-490.

12.11	Hawkins, B.E. and Evans, M.S. (1979) Seasonal cycles of zooplankton biomass in Southeastern Lake Michigan.
J. Great Lakes Res. 5 (3-4): 256-263.

12.12	Hudson, P.L., and Lesko, L.T. 2003. Free-living and Parasitic Copepods of the Laurentian Great Lakes: Keys
and Details on Individual Species. Ann Arbor, MI: Great Lakes Science Center Home Page.
http://www.glsc.usgs.gov/greatlakescopepods/

12.13	Hudson, P.L., Reid, J.W., Lesko, L.T. & Selgeby, J.H. (1998) Cyclopoid and Harpacticoid Copepods of the
Laurentian Great Lakes. Ohio Biological Survey Bulletin NS 12(2).

12.14	Makarewicz, J.C. & Jones, D.H. (1990) Occurrence of Bythotrephes cederstromei in Lake Ontario offshore
waters. J. Great Lakes Res. 16(1): 143-147.

12.15	Mauchline, J. 1980. The biology of mysids and euphausiids. Advances in Marine Biology 18:373-681.

12.16	Ojaveer, H., L.A. Kuhns, R.P. Barbiero and M.L. Tuchman. 2001. Distribution and population characteristics of
Cercopagispengoi in Lake Ontario. J. Great Lakes Res. 27:10-18.

12.17	Rivier, I.K. 1998. The Predatory Cladocera (Onychopoda: Podonidae, Polyphemidae, Cercopagidae) and
Leptodorida of the World. Backhuys Publishers, Leiden, The Netherlands, pp.213.

12.18	Shea, M.A. & Makarewicz, J.C. (1989) Production and trophic interactions ofMysis relicta in Lake Ontario. J.

Great Lakes Res. 15(2): 223-232.

12.19	Stemberger, R.S. 1979. A guide to rotifers of the Laurentian Great Lakes. U.S. Environmental Protection
Agency, Rept. No. EPA 600/4-79-021, 185 pp.

LG403, Revision 07, July 2016

Page 11

-------
Sampling and Analytical Procedures
for GLNPO's WQS

FIGURE 1: ZOOPLANKTON SAMPLE SPLITTING DIAGRAM

ORIGINAL
SAMPLE

\K

1/21

M/

Nk

1/21 This sample portion is
	 held until needed

N/

1/2

n-2



N/

\k

1/2n 2 This sample portion is counted
"D" sample

r,_ -"j	'j

1/2	1/2 This sample portion is counted

\k

1/2'

LEGEND:

"C" sample

N/

1/2 Both sample portions counted

'B" sample "A" sample

"A" and "B" sample:

"C":

"D":

the final split level

these sample portions are the two final sample volumes
the first preceding sample division
the second preceding sample division

NOTE: The actual final sample division will be determined by the density of the organisms in the original sample. The
first sample volume must have at least 200 organisms but not more than 400 organisms.

Page 12

LG403, Revision 07, July 2016

-------
Standard Operating Procedure for Zooplankton Analysis

APPENDIX 1: CRUSTACEAN FORMULA FACTORS

SPECCODE

Species

LNA

B

Species Used

Reference

ACAVERN

Acanthocyclops
vernalis

1.66

3.97

Mesocyclops edax

Rosen 1981

ACRHARP

Acroperus harpae

1.167

0.85

Acroperus harpae

Dumont et al., 1975

ALNGLOB

Alonella qlobulosa

2.1

2.26

Alonella exigua w
eggs

Dumont et al., 1975

ALOAFFI

Alona affinis

2.768

3.84

Alona affinis

Dumont et al., 1975

ALOGUTT

Alona guttata

2.768

3.84

Alona affinis

Dumont et al., 1975

ALOQUAD

Alona

quadrangularis

2.768

3.84

Alona affinis

Dumont et al., 1975

ALORECT

Alona rectangula

2.768

3.84

Alona affinis

Dumont et al., 1975

ALOSP

Alona spp.

2.768

3.84

Alona affinis

Dumont et al., 1975

BOSLONG

Bosmina
longirostris

2.712

2.53

Bosmina longirostris

Bottrell et al., 1976

BOSSP

Bosmina spp.

2.712

2.53

Bosmina longirostris

Bottrell et al., 1976

BYTLONG

Bythotrephes
longimanus

2.83

2.09

Bythotrephes
cederstroemi

Makarewicz & Jones (1990)

CALCOPE

Calanoid
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

CAMRECT

Camptocercus
rectirostris

2.768

3.84

Alona affinis

Dumont et al., 1975

CAMSP

Camptocercus
spp.

2.768

3.84

Alona affinis

Dumont et al., 1975

CANCOPE

Canthocamptus
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

CANOREG

Canthocamptus
oregonensis

1.59

2.59

generic calanoid

Burgess et al. 2015

CANROBE

Canthocamptus
robertcokeri

1.59

2.59

generic calanoid

Burgess et al. 2015

CANSP

Canthocamptus
spp.

1.59

2.59

generic calanoid

Burgess et al. 2015

CECPENG

Cercopagis
pengoi

0.488

2.98

Cercopagis pengoi

Ojaveer et al. 2001

CERLACU

Ceriodaphnia
lacustris

2.83

3.15

Ceriodaphnia
reticulata

Pace & Orcutt1981

CERRECT

Ceriodaphnia
reticulata

2.83

3.15

Ceriodaphnia
reticulata

Pace & Orcutt1981

CERSP

Ceriodaphnia spp.

2.83

3.15

Ceriodaphnia
reticulata

Pace & Orcutt1981

CHYDORI

Chydoridae

4.543

3.64

Chydorus sphaericus

Rosen 1981

CHYSPHA

Chydorus
sphaericus

4.543

3.64

Chydorus sphaericus

Rosen 1981

COPNAUP

Copepod nauplii

1.953

2.4

pooled copepod

Bottrell et al., 1976

CYCCOPE

Cyclops
copepodites

1.66

3.97

Mesocyclops edax

Rosen 1981

LG403, Revision 07, July 2016

Page 13

-------
Sampling and Analytical Procedures
for GLNPO's WQS

SPECCODE

Species

LNA

B

Species Used

Reference

CYCSTRE

Cyclops strenuus

1.66

3.97

Mesocyciops edax

Rosen 1981

DAPAMBI

Daphnia ambigua

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPCATA

Daphnia catawba

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPDUBI

Daphnia dubia

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPGALEM

Daphnia galeata
mendotae

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPLAEV

Daphnia iaevis

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPLONG

Daphnia
iongiremis

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPLUMH

Daphnia iumhoitzi

0.056

2.84

Daphnia 'pooled' with
correction for spine

Dumont et al., 1975, with a correction
removing proportion of length
representing spine (0.58*length)
(Cornell)

DAPMIDD

Daphnia
middendorffiana

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPPARV

Daphnia parvuia

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPPULE

Daphnia puiex

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPPULI

Daphnia puiicaria

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPRETR

Daphnia
retrocurva

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPROSE

Daphnia rosea

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPSCHO

Daphnia
schoedieri

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DAPSP

Daphnia spp.

1.603

2.84

Daphnia 'pooled'

Dumont et al., 1975

DIACOPE

Diaptomid
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

DIAPT

Diaptomidae

1.59

2.59

generic calanoid

Burgess et al. 2015

DIPBIRG

Diaphanosoma
birgei

1.289

3.04

Diaphanosoma
brachyrum

Rosen 1981

DIPSP

Diaphanosoma
spp.

1.289

3.04

Diaphanosoma
brachyrum

Rosen 1981

DIYNANU

Diacyciops nanus

1.66

3.97

Mesocyciops edax

Rosen 1981

DIYTHOM

Diacyciops
thomasi

1.66

3.97

Mesocyciops edax

Rosen 1981

EPICOPE

Epischura
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

EPILACU

Epischura
iacustris

1.59

2.59

generic calanoid

Burgess et al. 2015

EUBCORE

Eubosmina
coregoni

2.712

2.53

Bosmina longirostris

Bottrell et al., 1976

EUELAME

Eurycercus
iameilatus

2.1

2.26

Alonella exigua w
eggs

Dumont et al., 1975

EURAFFI

Eurytemora affinis

1.59

2.59

generic calanoid

Burgess et al. 2015

EURCOPE

Eurytemora
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

EUYAGIL

Eucyciops agiiis

1.66

3.97

Mesocyciops edax

Rosen 1981

Page 14

LG403, Revision 07, July 2016

-------
Standard Operating Procedure for Zooplankton Analysis

SPECCODE

Species

LNA

B

Species Used

Reference

EUYCOPE

Eucyclops
copepodites

1.66

3.97

Mesocyclops edax

Rosen 1981

EUYPRIO

Eucyclops
prionophorus

1.66

3.97

Mesocyclops edax

Rosen 1981

EUYELEG

Eucyclops
elegans

1.66

3.97

Mesocyclops edax

Rosen 1981

GRASP

Graptoleberis sp.

2.768

3.84

Alona affinis

Dumont et al., 1975

HALSP

Halicyclops spp.

1.66

3.97

Mesocyclops edax

Rosen 1981

HARCOPE

Harpacticoid
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

HARSP

Harpacticoida
spp.

1.59

2.59

generic calanoid

Burgess et al. 2015

HOLGIBB

Holopedium
gibberum

2.073

3.19

Holopedium
gibberum

Persson & Ekbohm 1980 original
coefficients modified for total
length (foot * 4)

ILYACUT

llyocryptus
acutifrons

2.768

3.84

Alona affinis

Dumont et al., 1975

ILYSP

llyocryptus spp.

2.768

3.84

Alona affinis

Dumont et al., 1975

ILYSPIN

llyocryptus
spinifer

2.768

3.84

Alona affinis

Dumont et al., 1975

LATSETI

Latona setifera

1.289

3.04

Diaphanosoma
brachyrum

Rosen 1981

LEOASHL

Leptodiaptomus
ashlandi

1.59

2.59

generic calanoid

Burgess et al. 2015

LEOMINU

Leptodiaptomus
minutus

1.59

2.59

generic calanoid

Burgess et al. 2015

LEOSICI

Leptodiaptomus
sicilis

1.59

2.59

generic calanoid

Burgess et al. 2015

LEOSICO

Leptodiaptomus
siciloides

1.59

2.59

generic calanoid

Burgess et al. 2015

LETKIND

Leptodora kindti

-0.822

2.67

Leptodora kindti

Rosen 1981

LEYQUAD

Leydigia
quadrangularis

2.768

3.84

Alona affinis

Dumont et al., 1975

LEYSP

Leydigia spp.

2.768

3.84

Alona affinis

Dumont et al., 1975

LIMCOPE

Limnocalanus
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

LIMMACR

Limnocalanus
macrurus

1.59

2.59

generic calanoid

Burgess et al. 2015

MACLAT

Macrothrix
laticornis

2.768

3.84

Alona affinis

Dumont et al., 1975

MACSP

Macrothrix spp.

2.768

3.84

Alona affinis

Dumont et al., 1975

MARALBI

Macrocyclops
albidus

1.66

3.97

Mesocyclops edax

Rosen 1981

MESCOPE

Mesocyclops
copepodites

1.66

3.97

Mesocyclops edax

Rosen 1981

MESEDAX

Mesocyclops

1.66

3.97

Mesocyclops edax

Rosen 1981

LG403, Revision 07, July 2016

Page 15

-------
Sampling and Analytical Procedures
for GLNPO's WQS

SPECCODE

Species

LNA

B

Species Used

Reference



edax









MICRUBE

Microcyclops
rubellus

1.66

3.97

Mesocyclops edax

Rosen 1981

MOIMICR

Moina micrura

1.889

2.57

Moina micrura

Dumont et al., 1975

MYSRELI

Mysis diluviana

1.266

2.72

Mysis relicta

Rudstam et al. 2008

ORTMODE

Orthocyclops
modestus

1.66

3.97

Mesocyclops edax

Rosen 1981

PARCHIT

Paracyclops
chittoni

1.66

3.97

Mesocyclops edax

Rosen 1981

PLEDENT

Pleuroxus
denticulatus

2.768

3.84

Alona affinis

Dumont et al., 1975

PLEPROC

Pleuroxus
procurvus

2.768

3.84

Alona affinis

Dumont et al., 1975

POYPEDI

Polyphemus
pediculus

2.779

2.15

Polyphemus
pediculus

Rosen 1981

SCAPSP

Scapholeberis
spp.

2.416

2.7

Scapholeberis
mucronata

Dumont et al., 1975

SCAPAURI

Scapholeberis
aurita

2.416

2.7

Scapholeberis
mucronata

Dumont et al., 1975

SENCALA

Senecella
calanoides

1.59

2.59

generic calanoid

Burgess et al. 2015

SENCOPE

Senecella
copepodites

1.59

2.59

generic calanoid

Burgess et al. 2015

SIDCRYS

Sida crystallina

2.054

2.19

Sida crystallina

Rosen 1981

SKIOREG

Skistodiaptomus
oregonensis

1.59

2.59

generic calanoid

Burgess et al. 2015

SKI PALL

Skistodiaptomus
pallidus

1.59

2.59

generic calanoid

Burgess et al. 2015

SKIREIG

Skistodiaptomus
reighardi

1.59

2.59

generic calanoid

Burgess et al. 2015

TROCOPE

Tropocyclops
copepodites

1.66

3.97

Mesocyclops edax

Rosen 1981

TROPRASM

Tropocyclops

prasinus

mexicanus

1.66

3.97

Mesocyclops edax

Rosen 1981

Page 16

LG403, Revision 07, July 2016

-------
Standard Operating Procedure for Zooplankton Analysis

APPENDIX 2: ROTIFER BIOMASS FORMULA FACTORS

SPECCODE

Species

EQ#

FF

%BV

WW:DW

ASCECAU

Ascomorpha
ecaudis

1

0.12

0

0.1

ASCOVAL

Ascomorpha
ovalis

1

0.12

0

0.1

ASCSALT

Ascomorpha
saltans

1

0.12

0

0.1

ASCSP

Ascomorpha spp.

1

0.12

0

0.1

ASPBRIG

Asplanchna
briqhtwelli

1

0.23

0

0.039

ASPHERR

Asplanchna
herricki

1

0.23

0

0.039

ASPPRIO

Asplanchna
priodonta

1

0.23

0

0.039

BRAANGU

Brachionus
angularis

1

0.12

0.1

0.1

BRABIDE

Brachionus
bidentata

1

0.12

0.1

0.1

BRABUDA

Brachionus
budapestinensis

1

0.12

0.1

0.1

BRACALC

Brachionus
calyciflorus

1

0.12

0.1

0.1

BRACAUD

Brachionus
caudatus

1

0.12

0.1

0.1

BRADIVE

Brachionus
diversicornis

1

0.12

0.1

0.1

BRAHAVA

Brachionus
havanaensis

1

0.12

0.1

0.1

BRAQUAD

Brachionus
quadridentatus

1

0.12

0.1

0.1

BRARUBE

Brachionus
rubens

1

0.12

0.1

0.1

BRASP

Brachionus spp.

1

0.12

0.1

0.1

BRAURCE

Brachionus
urceolaris

1

0.12

0.1

0.1

BRAVARI

Brachionus
variabilis

1

0.12

0.1

0.1

CEPINTU

Cephalodella
intuta

1

0.1

0.05

0.1

CEPSP

Cephalodella spp.

1

0.1

0.05

0.1

COLMUTA

Collotheca
mutabilis

2

1.8

0

0.1

COLPELA

Collotheca
pelagica

2

1.8

0

0.1

COLSP

Collotheca spp.

2

1.8

0

0.1

LG403, Revision 07, July 2016

Page 17

-------
Sampling and Analytical Procedures
for GLNPO's WQS

SPECCODE

Species

EQ#

FF

%BV

WW:DW

CONNATA

Conochiloides
natans

3

0.26

0

0.1

CONSP

Conochiloides
spp.

3

0.26

0

0.1

COOUNIC

Conochiius
unicornis

3

0.26

0

0.1

COUSP

Coiureila spp.

1

0.1

0.05

0.1

DICSP

Dicranophorus
spp.

1

0.035

0

0.1

ENCSP

Encentrum spp.

1

0.1

0.05

0.1

EUCALAT

Euchianis aiata

1

0.1

0.05

0.1

EUCCALP

Euchianis caipidia

1

0.1

0.05

0.1

EUCDILA

Euchianis dilatata

1

0.1

0.05

0.1

EUCMENE

Euchianis meneta

1

0.1

0.05

0.1

EUCSP

Euchianis spp.

1

0.1

0.05

0.1

FILLONG

Filinia longiseta



0.52

0.01

0.1

FILTERM

Filinia terminalis



0.52

0.01

0.1

GASSP

Gastropus spp.

1

0.2

0

0.1

GASSTYL

Gastropus stylifer

1

0.2

0

0.1

HEXMIRA

Hexarthra mira

1

0.13

0.33

0.1

KELBOST

Kellicottia
bostoniensis

1

0.03

0.015

0.1

KELLONG

Kellicottia
lonqispina

1

0.03

0.015

0.1

KERCOCH

Keratella
cochlearis

1

0.02

0

0.1

KERCOCHH

Keratella

cochlearis hispida

1

0.02

0

0.1

KERCOCHT

Keratella
cochlearis f. tecta

1

0.02

0

0.1

KERCRAS

Keratella crassa

1

0.02

0

0.1

KEREARL

Keratella earlinae

1

0.02

0

0.1

KERHIEM

Keratella hiemalis

1

0.22

0.05

0.1

KERQUAD

Keratella quadrata

1

0.22

0.05

0.1

KERSP

Keratella spp.

1

0.02

0

0.1

KERTAUR

Keratella
taurocephala

1

0.22

0.05

0.1

KERTEST

Keratella testudo

1

0.22

0.05

0.1

KERVALGT

Keratella valga f.
tropica

1

0.22

0.05

0.1

Page 18

LG403, Revision 07, July 2016

-------
Standard Operating Procedure for Zooplankton Analysis

SPECCODE

Species

EQ#

FF

%BV

WW:DW

LECFLEX

Lecane flexilis

1

0.1

0.05

0.1

LECSP

Lecane spp.

1

0.1

0.05

0.1

LECTENU

Lecane tenuiseta

1

0.1

0.05

0.1

LECTUDI

Lecane tudicola

1

0.1

0.05

0.1

LEPSP

Lepadella spp.

1

0.1

0.05

0.1

LEPTRIP

Lepadella triptera

1

0.1

0.05

0.1

MONCOPE

Monostyla copeis

1

0.12

0.1

0.1

MONLUNA

Monostyla lunaris

1

0.12

0.1

0.1

MONSP

Monostyla spp.

1

0.12

0.1

0.1

MYTSP

Mytilina spp.

1

0.1

0.05

0.1

NOOSP

Notommata spp.

1

0.035

0

0.1

NOTACUM

Notholca
acuminata

1

0.035

0

0.1

NOTCAUD

Notholca caudata

1

0.035

0

0.1

NOTFOLI

Notholca foliacea

1

0.035

0

0.1

NOTLABI

Notholca labis

1

0.035

0

0.1

NOTLAUR

Notholca
laurentiae

1

0.035

0

0.1

NOTMICH

Notholca
michiganensis

1

0.035

0

0.1

NOTSP

Notholca spp.

1

0.035

0

0.1

NOTSQUA

Notholca
squamula

1

0.035

0

0.1

NOTSTRI

Notholca striata

1

0.035

0

0.1

PLAPATU

Platyias patulus

1

0.22

0.05

0.1

PLOHUDS

Ploesoma hudsoni

1

0.1

0

0.1

PLOLENT

Ploesoma
lenticulare

1

0.1

0

0.1

PLOSP

Ploesoma spp.

1

0.1

0

0.1

PLOTRUN

Ploesoma
truncatum

1

0.1

0

0.1

POLDOLI

Polyarthra
dolichoptera

1

0.28

0.1

0.1

POLEURY

Polyarthra
euryptera

1

0.28

0.1

0.1

POLMAJO

Polyarthra major

1

0.28

0.1

0.1

POLREMA

Polyarthra remata

1

0.28

0.1

0.1

POLSP

Polyarthra spp.

1

0.28

0.1

0.1

POLVULG

Polyarthra vulgaris

1

0.28

0.1

0.1

POMSULC

Pompholyx
sulcata

1

0.15

0

0.1

ROTBDEL

Rotifera bdelloid

1

0.1

0

0.1

SYNSP

Synchaeta spp.

1

0.1

0

0.1

LG403, Revision 07, July 2016

Page 19

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Sampling and Analytical Procedures
for GLNPO's WQS

SPECCODE

Species

EQ#

FF

%BV

WW:DW

TESPARV

Testudinella parva

1

0.08

0.1

0.1

TRCPOCI

Trichotria pocillum

1

0.1

0.05

0.1

TRCPOCI

Trichotria pocillum

1

0.1

0.05

0.1

TRCSP

Trichotria spp.

1

0.1

0.05

0.1

TRCTETR

Trichotria tetractis

1

0.1

0.05

0.1

TRICAPU

Trichocerca
capucina

3

0.52

0.006

0.1

TRICYLI

Trichocerca
cylindrica

3

0.52

0.006

0.1

TRIELON

Trichocerca
elonqata

3

0.52

0.006

0.1

TRIIERN

Trichocerca iernis

3

0.52

0.006

0.1

TRIINSO

Trichocerca
insolens

3

0.52

0.006

0.1

TRILATA

Trichocerca lata

3

0.52

0.006

0.1

TRIMULT

Trichocerca
multicrinis

3

0.52

0.006

0.1

TRIPORC

Trichocerca
porcellus

3

0.52

0.006

0.1

TRIPUSI

Trichocerca
pusilla

3

0.52

0.006

0.1

TRIRATT

Trichocerca rattus

3

0.52

0.006

0.1

TRIROUS

Trichocerca
rousseleti

3

0.52

0.006

0.1

TRISIMI

Trichocerca similis

3

0.52

0.006

0.1

TRISP

Trichocerca spp.

3

0.52

0.006

0.1

Page 20

LG403, Revision 07, July 2016

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